Neural Mechanisms Mediating Hypersecretion And Motility Patterns Induced By Enterotoxins
Funder
National Health and Medical Research Council
Funding Amount
$415,250.00
Summary
This project aims to identify the nerve cells that are responsible for the massive oversecretion of water and salt seen with cholera and other diseases producing diarrhoea. Many of these disease act through specific toxins and, although the biochemical targets of these toxins are reasonably well understood, the nerve cells on which they act have never been identified. Furthermore, the mechanisms that couple the oversecretion with a massive increase in the propulsive activity of the intestine are ....This project aims to identify the nerve cells that are responsible for the massive oversecretion of water and salt seen with cholera and other diseases producing diarrhoea. Many of these disease act through specific toxins and, although the biochemical targets of these toxins are reasonably well understood, the nerve cells on which they act have never been identified. Furthermore, the mechanisms that couple the oversecretion with a massive increase in the propulsive activity of the intestine are also unknown. We will investigate each of these questions using the small intestine of the guinea-pig, because the nerve circuit in this preparation is better understood than that of any other. Nerve cells that respond to three specific toxins, each known to activate the nervous system via different mechanisms, will be determined using intracellular recording methods, injection of marker dyes and methods that allow the identification of their neurochemistry. This will allow the functions of responsive nerve cells to be identified and their places in the circuits that control secretion and propulsion to be determined. This information will be correlated with studies in whole animals being undertaken in Sweden so that potential sites for intervention can be identified.Read moreRead less
Properties And Electro-Physiology Of The Intrinsic Nervous System
Funder
National Health and Medical Research Council
Funding Amount
$419,214.00
Summary
The gut contains a very large number of nerve cells which fall into several functionally distinct groups. We have identified virtually all these functional groups in the guinea-pig small intestine and have begun an analysis of the ways the different groups communicate with each other. We have developed methods to identify the functions of any nerve cell from which we record and have also developed novel methods for specifically stimulating individual functional classes of nerve cells that contac ....The gut contains a very large number of nerve cells which fall into several functionally distinct groups. We have identified virtually all these functional groups in the guinea-pig small intestine and have begun an analysis of the ways the different groups communicate with each other. We have developed methods to identify the functions of any nerve cell from which we record and have also developed novel methods for specifically stimulating individual functional classes of nerve cells that contact them. The aim of the proposed research is to exploit these methods to identify the chemicals used by specifc types of nerve cell in transmission of information to other nerve cells during the normal behaviour of the intestine. We will record the behaviour of individual nerve cells in the gut wall while stimulating specific nerve pathways that contact them. We will then use drugs that block the activity of the chemicals of interest (small proteins called tachykinins, and certain amine compounds) to try and block the transmission of information between the nerve cells involved. Identification of the nature of the chemicals used at specific connections between different functional groups of nerve cells in the gut will allow the design of drugs for treatment of gastrointestinal disorders that will have minimal side effects. Further because the chemicals that are used for communication in the gut are also found in the brain, the results will provide evidence about the functions of these chemicals elsewhere in the nervous system.Read moreRead less
Changes In Pelvic Autonomic Neurons After Spinal Nerve Injury
Funder
National Health and Medical Research Council
Funding Amount
$176,734.00
Summary
This project is about the effects of spinal injury on autonomic neurons that control the bladder, lower bowel and reproductive organs. One of the consequences of some types of spinal injury is that there are no signals being sent from the spinal cord to the nerve cells outside the cord, and this leads to poor bladder control, impotence, etc. We are mimicking this problem experimentally by damaging the spinal nerves that carry these signals. We have found that after this type of damage the pelvic ....This project is about the effects of spinal injury on autonomic neurons that control the bladder, lower bowel and reproductive organs. One of the consequences of some types of spinal injury is that there are no signals being sent from the spinal cord to the nerve cells outside the cord, and this leads to poor bladder control, impotence, etc. We are mimicking this problem experimentally by damaging the spinal nerves that carry these signals. We have found that after this type of damage the pelvic autonomic neurons make many new connections between each other, and the types of new connections depend on which spinal nerves have been injured. This leads to the question: are these new connections good or bad? ie are they helpful in trying to get organ control back to normal or will they stop the correct connections from the spinal cord from being made in the future? This project addresses these questions by using sophisticated techniques for staining and visualising individual nerve fibres growing out from the spinal cord. We will track how well these fibres grow back and connect with the pelvic autonomic neurons. In particular, we will see whether they make correct connections, and if these connections are influenced by the new fibres that have grown between the autonomic neurons in the interim period. We will also do physiological tests to see if the new connections have the correct function. The ultimate aim of these studies is not only to understand more about regeneration, but to see what determines whether the correct connections have been made - and ideally, to give us insight into how we can make regeneration work more quickly and accurately. We believe that this work is an important adjunct to other studies on spinal injury, which mostly focuses on regaining voluntary motor control (e.g. walking); however loss of bladder, bowel and reproductive function is another important quality of life issue for spinal injury patients.Read moreRead less
Cardiac Sympathetic Nerve Activity: Understanding Normal Control And The Causes Of The Increase In Heart Failure
Funder
National Health and Medical Research Council
Funding Amount
$531,125.00
Summary
Heart failure is a condition in which the heart muscle becomes weak and is unable to pump sufficient blood around the body to provide adequate perfusion of the organs. This results in breathlessness, lethargy, fatigue, mental confusion and eventually death. At present the life expectancy of patients with heart failure is poor, with a 5 year survival of 25% in men and 38% in women. It is the only form of heart disease that is increasing, the reason being that thousands of patients who have surviv ....Heart failure is a condition in which the heart muscle becomes weak and is unable to pump sufficient blood around the body to provide adequate perfusion of the organs. This results in breathlessness, lethargy, fatigue, mental confusion and eventually death. At present the life expectancy of patients with heart failure is poor, with a 5 year survival of 25% in men and 38% in women. It is the only form of heart disease that is increasing, the reason being that thousands of patients who have survived heart attacks or had coronary bypass operations go on to develop heart failure. In heart failure there is a very large increase in the activity of the nerves that stimulate cardiac rate and contractility, the cardiac sympathetic nerves. This increase in activity is detrimental, higher levels of activity predict greater morbidity and a reduced life span. The mechanisms causing the increase in cardiac sympathetic nerve activity are unknown, but greater understanding is essential if new and improved treatments are to be developed for patients with heart failure. Only two groups in the world measure cardiac nerve activity in conscious animals, neither is studying heart failure. We therefore have a unique opportunity to investigate the factors that control the activity of the cardiac nerves in the healthy state and to establish the causes of the increase in activity in heart failure. In particular, we will investigate how reflex control mechanisms, circulating hormones that are increased in heart failure and specific mechanisms in the brain act to control cardiac nerve activity in the normal state and what changes in these mechanisms lead to the preferential increase in cardiac nerve activity in heart failure. These findings will provide a detailed understanding of the mechanisms controlling cardiac nerve activity in the normal healthy state and increased knowledge of the factors that lead to the preferential activation of the cardiac nerves in heart failure.Read moreRead less
How The Intestinal Microenvironment Controls Propulsion And Mixing Of Food In The Gut: Parallel Transduction Pathways
Funder
National Health and Medical Research Council
Funding Amount
$1,157,350.00
Summary
This project will identify the mechanisms that control the mixing of food with digestive juices, the absoprtion of nutrients from the gut to the blood stream and the excretion of waste. Disruption of these processes causes significant health problems and is associated with normal aging and many diseases. We will identify nutrients and other food components (eg spices) that switch gut from mixing to propulsion and hence identify targets to treat disorders of gut movement.
The sphincter of Oddi is a valve-like structure, which regulates the flow of bile and pancreatic juice into the gut. The sphincter of Oddi is under complex control involving nerves and hormones. We know that abnormal sphincter of Oddi function (sphincter of Oddi dysfunction) is associated with a number of human diseases including acute pancreatitis. We are able to recognise abnormal sphincter activity, but we do not know what causes it. One possible reason may be that the nerves going to the sph ....The sphincter of Oddi is a valve-like structure, which regulates the flow of bile and pancreatic juice into the gut. The sphincter of Oddi is under complex control involving nerves and hormones. We know that abnormal sphincter of Oddi function (sphincter of Oddi dysfunction) is associated with a number of human diseases including acute pancreatitis. We are able to recognise abnormal sphincter activity, but we do not know what causes it. One possible reason may be that the nerves going to the sphincter along the bile duct (which carries bile from the liver and gallbladder) may be damaged due to the passage of gallstones or during surgery on the bile ducts or gallbladder. We know that the main bile duct is able to sense pressure changes within and communicate this information (via nerves) to the sphincter which inturn alters its activity to relieve the pressure. Where these nerves are located and the chemical messages they use, are unknown. The aim of this project is to gain some of this information. This knowledge may allow us to design different surgical procedures or develop drugs to prevent or manage the abnormal sphincter of Oddi.Read moreRead less